PDS3_DATA_SET_ID = VG1-J-PRA-3-RDR-LOWBAND-6SEC-V1.0 DATA_SET_NAME = VG1 JUP PRA CALIBRATED HI-RES LOW FREQ. REC. BAND DATA V1.0 START_TIME = 1979-01-06T00:00:34 STOP_TIME = 1979-04-13T23:59:08 ORIGINAL_DATA_SET_RELEASE_DATE = 1996-07-01 PRODUCER_FULL_NAME = DR. MICHAEL L. KAISER REFERENCES: Leblanc, Y., M.G. Aubier, A. Ortega-Molina, and A. Lecacheux, Overview of the Uranian Radio Emissions: Polarization and Constraints on Source Locations, J. Geophys. Res., Vol. 92, p. 15125, 1987. Warwick, J.W., J.B. Pearce, A.C. Riddle, J.K. Alexander, M.D. Desch, M.L. Kaiser, J.R. Thieman, T.D. Carr, S. Gulkis, A. Boischot, C.C. Harvey, and B.M. Pedersen, Voyager 1 Planetary Radio Astronomy Observations Near Jupiter, Science, Vol. 204, p. 995, 1979. DATA_SET_DESCRIPTION Data Set Overview ================= This data set (VG1-J-PRA-3-RDR-LOWBAND-6SEC-V1.0) contains data acquired by the Voyager-1 Planetary Radio Astronomy (PRA) instrument during the Jupiter encounter. The bounding time interval set for most Voyager 1 Jupiter PDS data sets is the Voyager project defined 'far encounter' mission phase boundary (1979-02-28 to 1979-03-22). Since, however, the PRA instrument is able to observe planetary phenomenon at much larger ranges than other fields and particles experiments, this boundary is artificial with respect to PRA. Hence, PRA lowband data provided here cover the entire Jupiter Encounter Phase (1979-01-06 to 1979-04-13). Data from beyond the far encounter interval is contained in the cruise data archive which is available from the NSSDC. VG1-J-PRA-3-RDR-LOWBAND-6SEC-V1.0 contains data at the highest time resolution possible during normal operations. The normal mode of PRA operations during the planetary encounters was to sweep through the two radio receiver bands, high band (40.5 to 1.5 MHz in 128 channels spaced 0.3072 MHz apart) and low band (1326.0 to 1.2 kHz in 70 channels spaced 19.2 kHz apart) in a period of 6 seconds. The receivers measured, on alternate samples, the left hand circular and right hand circular (radio definition) power. Measured Parameters =================== The data here are from the low frequency receiver band and are 'packaged' into spacecraft major frame records. Each major frame is 48 seconds long or eight sweeps through the PRA receiver. The data are calibrated and are given in units of 'millibels' which is 1000 times the log of the received power. Zero millbels corresponds to approximately 1.4 x 10^-21 W m^-2 Hz^-1, however, this value is never seen in practice. The minimum values detected, which includes receiver internal and spacecraft generated noise, are about 2300 to 2400 millibels, or about 3.5 x 10^-19 W m^-2 Hz^-1; even higher values are seen at the very lowest frequencies. The data format is ASCII and consists of a time indicator followed by an array containing the eight low band sweeps. Time is spacecraft event time (SCET) which is basically universal time at the spacecraft. Specifically, time is in the form of YYMMDD and seconds into YYMMDD. Both are written as I6. Example: July 1, 1979 at 12 hours SCET would be 790701, 43200. The seconds correspond, to the nearest second, to the start of the sweep (which occurs in PRA high band). The first value in low band (1326.0 kHz) occurs some 3.9 seconds after this time and samples at successively lower frequencies are spaced 0.03 seconds apart. Only one time is given for the entire major frame, thus the start of each sweep is the time given plus 6 times the sweep number minus 1 (i.e., 0 through 7). The data array is dimensioned as 71 X 8 and written as I4 format (i.e. 568I4). The '8' corresponds to the eight PRA sweeps. The lowest 68 of the 70 low band channels (1287.6 to 1.2 kHz) are in positions 2-69. Positions 70-71 should be ignored. Missing or bad data values are set to zero. In position 1 of each sweep is a status word where the 12 least significant bits have used, although not all 12 have meaning for PRA low band. Numbering those bits 0 for least significant to 11 for most significant, the bits that have meaning are as follows: bit 0: 15 dB attenuator in use when equal to 1 1: 30 dB attenuator in use when equal to 1 2: 45 dB attenuator in use when equal to 1 9,10 (together): polarization of first channel sampled (1326.0 kHz) according to the scheme: value bit 10 = 0 1 value bit 9 = 0 R L 1 L R Polarization at successively lower frequencies is opposite to the frequency above it, i.e. either a LRLR or an RLRL pattern. Successive 6-second sweeps start on the opposite polarization as the previous sweep as indicated in the status bits. Note that this polarization is the received polarization, not necessarily the emitted polarization. Correct interpretation of the received polarization depends on the antenna plane orientation relative to the radio source. A good description of this concept can be found in [LEBLANCETAL1987]. Missing or bad data values are set to zero. If the status word is zero, any data in that receiver sweep should be discarded. Data Coverage ============= Filename Records Start Stop ----------------------------------------------------------------------- Volume ID: VGPR_1201 PRA_I.TAB 35569 1979-01-06T00:00:34.000Z 1979-01-30T23:59:47.000Z PRA_II.TAB 39493 1979-01-31T00:00:35.000Z 1979-02-25T23:59:47.000Z PRA_III.TAB 41371 1979-02-26T00:00:35.000Z 1979-03-22T23:59:56.000Z PRA_IV.TAB 24587 1979-03-23T00:00:44.000Z 1979-04-13T23:59:08.000Z CONFIDENCE_LEVEL_NOTE = Confidence Level Overview ========================= The accuracy of calibration in the PRA low band is approximately 2 dB, except at frequencies below 100 kHz where it is somewhat worse. Interference from the Voyager power subsystem is a major problem to the PRA instrument, affecting many of the 70 low band channels. This interference manifests itself by abrupt changes in background levels. Some channels, notably 136 and 193 kHz, are almost always affected, whereas, others are only affected for short intervals. Usually, this interference is only a problem when the natural signals are weak.